The energy produced during the ramming of bighorn sheep (Ovis canadensis) would be expected to result in undesirable stresses in their frontal skull, which in turn would cause brain injury; yet, this animal seems to suffer no ill effects. In general, horn is made of an -keratin sheath covering a bone. Despite volumes of data on the ramming behavior of Ovis canadensis, the extent to which structural components of horn and horn-associated structure or tissue absorb the impact energy generated by the ramming event is still unknown. This study investigates the hypothesis that there is a mechanical relationship present among the ramming event, the structural constituents of the horn, and the horn-associated structure. The three-dimensional complex structure of the bighorn sheep horn was successfully constructed and modeled using a computed tomography (CT) scan and finite element (FE) method, respectively. Three different three-dimensional quasi-static models, including a horn model with trabecular bone, a horn model with compact bone that instead of trabecular bone, and a horn model with trabecular bone as well as frontal sinuses, were studied. FE simulations were used to compare distributions of principal stress in the horn and the frontal sinuses and the strain energy under quasi-static loading conditions. It was noticed that strain energy due to elastic deformation of the complex structure of horn modeled with trabecular bone and with trabecular bone and frontal sinus was different. In addition, trabecular bone in the horn distributes the stresses over a larger volume, suggesting a mechanical link between the structural constituents and the ramming event. This phenomenon was elucidated through the principal stress distribution in the structure. This study will help designers in choosing appropriate material combinations for the successful design of protective structures against a similar impact.
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February 2011
Research Papers
Finite Element Analysis of Ramming in Ovis canadensis
Parimal Maity,
Parimal Maity
Department of Mechanical Engineering, Composite Vehicle Research Center,
e-mail: parimal.iitk@gmail.com
Michigan State University
, 2727 Alliance Drive, Lansing, MI-48910
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Srinivasan Arjun Tekalur
Srinivasan Arjun Tekalur
Department of Mechanical Engineering, Composite Vehicle Research Center,
Michigan State University
, 2727 Alliance Drive, Lansing, MI-48910
Search for other works by this author on:
Parimal Maity
Department of Mechanical Engineering, Composite Vehicle Research Center,
Michigan State University
, 2727 Alliance Drive, Lansing, MI-48910e-mail: parimal.iitk@gmail.com
Srinivasan Arjun Tekalur
Department of Mechanical Engineering, Composite Vehicle Research Center,
Michigan State University
, 2727 Alliance Drive, Lansing, MI-48910J Biomech Eng. Feb 2011, 133(2): 021009 (9 pages)
Published Online: January 31, 2011
Article history
Received:
July 20, 2010
Revised:
November 22, 2010
Posted:
December 22, 2010
Published:
January 31, 2011
Online:
January 31, 2011
Citation
Maity, P., and Tekalur, S. A. (January 31, 2011). "Finite Element Analysis of Ramming in Ovis canadensis." ASME. J Biomech Eng. February 2011; 133(2): 021009. https://doi.org/10.1115/1.4003321
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